Aircraft wing structure and control system

1. A control system, comprising: a sensor configured to measure a deflection angle of a first aileron of a wing of an aircraft, the first aileron being configured to rotate upwards from a first aileron neutral position and downwards from the first aileron neutral position; a motor configured to rotate a second aileron of the wing, the second aileron being configured to rotate upwards from a second aileron neutral position and to not rotate downwards from the second aileron neutral position; and a controller coupled to the sensor and configured to: receive the deflection angle from the sensor, determine a target deflection angle for the second aileron using the deflection angle, and cause the motor to rotate the second aileron to the target deflection angle.

2. The control system of claim 1 , wherein to determine the target deflection angle the controller is configured to set the target deflection angle equal to the deflection angle of the first aileron.

3. The control system of claim 1 , wherein to determine the target deflection angle the controller is configured to: when the first aileron is deflected upwards from the first aileron neutral position, set the target deflection angle of the second aileron equal to the deflection angle of the first aileron; and when the first aileron is deflected downwards from the first aileron neutral position, set the target deflection angle of the second aileron to a second aileron neutral position.

4. The control system of claim 1 , wherein to determine the target deflection angle the controller is configured to: determine a speed of the aircraft; and when the speed of the aircraft is above a predetermined speed threshold, set the target deflection angle of the second aileron to a second aileron neutral position.

5. The control system of claim 1 , wherein the controller is configured to determine a dynamic pressure of air surrounding the aircraft, and wherein the target deflection angle of the second aileron is at least partially determined by the dynamic pressure.

6. The control system of claim 1 , wherein to determine the target deflection angle the controller is configured to: determine an initial target deflection angle for the second aileron using the deflection angle of the first aileron determine a speed of the aircraft; determine a scaling factor based upon the speed of the aircraft; and multiply the initial target deflection angle by the scaling factor to determine the target deflection angle.

7. An aircraft, comprising: a wing including a Lam aileron pivotally connected to a trailing edge of the wing; a motor connected to the Lam aileron and configured to move the Lam aileron; and a controller configured to: detect a position of a control surface of the aircraft, determine a target position using the position of the control surface of the aircraft, and cause the motor to position the Lam aileron in the target position.

8. The aircraft of claim 7 , wherein to determine the target position, the controller is configured to set the target position equal to the position of the control surface.

9. The aircraft of claim 7 , wherein to determine the target position, the controller is configured to: when the control surface is in an up position, set the target position equal to the position of the control surface; and when the control surface is in a down or neutral position, setting the target position to a neutral position.

10. The aircraft of claim 7 , wherein the controller is configured to determine a speed of the aircraft, and wherein the target position is at least partially determined by the speed of the aircraft.

11. The aircraft of claim 7 , wherein the control surface is an aileron rotatably coupled to the wing.

12. The aircraft of claim 11 , wherein the Lam aileron is coupled to the wing and the Lam aileron is configured to rotate upwards from a neutral position and not to rotate downwards from the neutral position.

13. The aircraft of claim 12 , wherein the control surface is connected to the wing and the Lam aileron is inboard of the control surface.

14. The aircraft of claim 7 , wherein the controller is configured to determine a dynamic pressure of air surrounding the aircraft, and wherein the target position is at least partially determined by the dynamic pressure.

15. A method, comprising: determining a deflection angle of a first aileron of a wing of an aircraft; determining a target deflection angle for a second aileron of the wing using the deflection angle of the first aileron; and causing the second aileron to rotate to the target deflection angle.

16. The method of claim 15 , wherein determining the target deflection angle further comprises setting the target deflection angle equal to the deflection angle of the first aileron.

17. The method of claim 15 , wherein determining the target deflection angle further comprises: when the first aileron is deflected upwards from a first aileron neutral position, setting the target deflection angle equal to the deflection angle of the first aileron; and when the first aileron is deflected downwards from the first aileron neutral position, setting the target deflection angle of the second aileron to a second aileron neutral position.

18. The method of claim 15 , wherein determining the target deflection angle further comprises: determining a speed of the aircraft; and when the speed of the aircraft is above a predetermined speed threshold, setting the target deflection angle of the second aileron to a second aileron neutral position.

19. The method of claim 15 , further comprising determining a dynamic pressure of air surrounding at least a portion of the aircraft, and wherein the target deflection angle of the second aileron is at least partially determined by the dynamic pressure.

20. The method of claim 15 , wherein determining the target deflection angle further comprises: determining an initial target deflection angle for the second aileron using the deflection angle of the first aileron determining a speed of the aircraft; determining a scaling factor based upon the speed of the aircraft; and multiplying the initial target deflection angle by the scaling factor to determine the target deflection angle.